#! /mnt/svejk0/ras/ras/cfg/master_cfg #----------------------------------------------------------------------------- # CONFIG_INTERACTIVE_MODE_ON - Value of 1 causes routine to prompt for # missing config file keywords, otherwise an # error message is printed and the routine fails #----------------------------------------------------------------------------- CONFIG_INTERACTIVE_MODE_ON 0 #----------------------------------------------------------------------------- # Flyby Setup & IO Pass Information # spacecraft - specifies the name of a SPICE recognized observer body # target - specifies the name of a SPICE recognized target body # data_take_number - Cruise IEB's < 30, Tour IEB's > 30 # if larger than 255, it will roll back to 0 # Reset_data_take_number - Use this option when data take number is not properly # set during uplink process # target_name - use target # IO_PDT_configfile - PDT config specifies SPICE files for that sequence # IO_smtfile_1 - path and file name of SMT file received from IO # (Science Planning Web Site) # IO_smtfile_2 - path and file name of SMT file # (often: PEF are 2 Sequences, SMT are 1 seqence) # IO_peffile - path and file name of PEF file received from IO # (Science Planning Web Site) # IEB_number_in_PEF - PEF file can contain multiple IEBs. # If 0 config_merge will prompt user #----------------------------------------------------------------------------- spacecraft Cassini target Titan data_take_number 195 IO_PDT_configfile /afs/jpl/group/casops/dom/data/main/pdt_config/S50_ssup_psiv1_090310_pdt.cfg IO_smtfile_1 /afs/jpl/group/casradar/tour/s50/S50_090304.rpt IO_peffile /afs/jpl.nasa.gov/group/casops/dom/data/seq/S50/pef/z0500c.pef IEB_number_in_PEF 5 #----------------------------------------------------------------------------- # Kernel_Dispaly Parameters (to control plotting) # plot_tool - specifies whether xmgr or xmgrace is used for making plots # Valid values for: plot_tool # xmgrace - Use xmgrace (this is the default if this keyword is absent) # xmgr - alternate older plotting tool #----------------------------------------------------------------------------- plot_tool xmgrace #----------------------------------------------------------------------------- # RMSS IO Parameters (populated by the config_merge process) # IEB_Trigger - SCLK value of trigger given in PEF file # This is second trigger (not IDAPT trigger) # IEB_delta_trigger - Delta trigger time update due to live ivp update # IDAPT_delta - time prior to IEB_Trigger. Value always second prior to Trigger # IEB_duration - time from IEB_Trigger to Halt # DataVolumeAllocation - time from IEB_Trigger to Halt # DataRateTime_1 - Time of Data Rate Mode Change # DataRateTime_2 - Time of Data Rate Mode Change # DataRateTime_3 - Time of Data Rate Mode Change # DataRateTime_4 - Time of Data Rate Mode Change # DataRateTime_5 - Time of Data Rate Mode Change # DataRateTime_6 - Time of Data Rate Mode Change # DataRateTime_7 - Time of Data Rate Mode Change # DataRateTime_8 - Time of Data Rate Mode Change # DataRateTime_9 - Time of Data Rate Mode Change # DataRate_1 - The S/C Date Rate starting at correlated DateRateTime # DataRate_2 - The S/C Date Rate starting at correlated DateRateTime # DataRate_3 - The S/C Date Rate starting at correlated DateRateTime # DataRate_4 - The S/C Date Rate starting at correlated DateRateTime # DataRate_5 - The S/C Date Rate starting at correlated DateRateTime # DataRate_6 - The S/C Date Rate starting at correlated DateRateTime # DataRate_7 - The S/C Date Rate starting at correlated DateRateTime # DataRate_8 - The S/C Date Rate starting at correlated DateRateTime # DataRate_9 - The S/C Date Rate starting at correlated DateRateTime # PowerTransitionTime_1 - Time of Power Transition Allocation # PowerTransitionTime_2 - Time of Power Transition Allocation # PowerTransitionTime_3 - Time of Power Transition Allocation # PowerTransitionTime_4 - Time of Power Transition Allocation # PowerTransitionTime_5 - Time of Power Transition Allocation # PowerTransitionTime_6 - Time of Power Transition Allocation # PowerTransitionTime_7 - Time of Power Transition Allocation # PowerTransitionTime_8 - Time of Power Transition Allocation # PowerTransitionTime_9 - Time of Power Transition Allocation # PowerAllocation_1 - Power Level Allocation (ie: 0,55,86) # PowerAllocation_2 - Power Level Allocation (ie: 0,55,86) # PowerAllocation_3 - Power Level Allocation (ie: 0,55,86) # PowerAllocation_4 - Power Level Allocation (ie: 0,55,86) # PowerAllocation_5 - Power Level Allocation (ie: 0,55,86) # PowerAllocation_6 - Power Level Allocation (ie: 0,55,86) # PowerAllocation_7 - Power Level Allocation (ie: 0,55,86) # PowerAllocation_8 - Power Level Allocation (ie: 0,55,86) # PowerAllocation_9 - Power Level Allocation (ie: 0,55,86) #----------------------------------------------------------------------------- IEB_Trigger 1622979989 IEB_delta_trigger 0 s IDAPT_delta 0 s IEB_duration 33720 s DataVolumeAllocation 8.226e+08 DataRateTime_1 1622979689 DataRateTime_2 1622980589 DataRateTime_3 1622993489 DataRateTime_4 1623014009 DataRate_1 7600 DataRate_2 0 DataRate_3 364800 DataRate_4 0 PowerTransitionTime_1 1622979692 PowerTransitionTime_2 1622993531 PowerTransitionTime_3 1623014001 PowerAllocation_1 55 W PowerAllocation_2 86 W PowerAllocation_3 55 W #----------------------------------------------------------------------------- # Epoch Setup # epoch_selection - specifies how the epoch time for this config file is set # Valid values for: epoch_selection # absolute - The value specified by epoch_time is used directly # closest_flyby - The closest approach time nearest to epoch_time is used # epoch_accuracy - The precision of the search for the closest flyby time # epoch_time - The epoch time to use, or the starting point in the search for # the epoch time to use. #----------------------------------------------------------------------------- epoch_selection closest_flyby epoch_accuracy 1 ms epoch_time 2009-157T20:00:00.000 #----------------------------------------------------------------------------- # SAR Pointing and IVD Setup # look_direction - Specifies which side to tilt the 5 beams towards # Valid values for: look_direction # right - Look to the right when you look along the velocity direction from # behind the spacecraft. # left - Look to the left when you look along the velocity direction from # behind the spacecraft. # sc_orientation - Specifies whether plus or minus X should be closest to the # velocity direction during the IVD interval. # ie., resolve the 180 degree ambiguitiy in SAR pointing. # Valid values for: sc_orientation # -x_direction_to_velocity - Hold -X towards the velocity direction # +x_direction_to_velocity - Hold +X towards the velocity direction # ivd_file - the name of the output IVD file to create # start_time_ivd - Start time of SAR profile - used to create ivd files # time_step_ivd - used to create ivd files # end_time_ivd - End time of SAR profile - used to create ivd files # ivd_time_pad - amount of time to add to the IVD time interval on each side. # This creates an IVD file valid for a longer time interval. # ivd_fractional_second - determine fractional time in generating IVD #----------------------------------------------------------------------------- look_direction left sc_orientation -x_direction_to_velocity ivd_file RADAR_S50_SOP_T56_081204.ivd start_time_ivd -25 min time_step_ivd 1.0 s end_time_ivd 25 min ivd_time_pad 7 min ivd_fractional_second .117 s #----------------------------------------------------------------------------- # Default Spice Directories # hasekSPICEdir - Default path to SPICE files on hasek (except ckernels) # Note: Also default for unknown workstation # (according to config_merge) # casradar2SPICEdir - Default path to SPICE files on casradar2 (except ckernels) #----------------------------------------------------------------------------- hasekSPICEdir /home/ras/dat/naif/ casradar2SPICEdir /cas/ancillary/ops/NAIF/ #----------------------------------------------------------------------------- # Spice File Setup # spice_directory - Directory where Spice files reside (except ckernels) # If not present, fully qualified names must be used # tour_ephemeris - SPICE file: the spacecraft ephemeris file # sclk_kernel - SPICE file: sclk to UTC translation data # time_kernel - SPICE file: leapseconds data # instrument_kernel - SPICE file: field of view data for an instrument # frame_kernel - SPICE file: instrument frame definitions # planetary_constants_kernel - SPICE file: GM, radii etc for planets # solarsystem_ephemeris_kernel - SPICE file: ephemeris data for planet # barycenters # planet_ephemeris_kernel - SPICE file: ephemeris data for specific planet #----------------------------------------------------------------------------- spice_directory /home/ras/dat/naif/ tour_ephemeris sp/090708R_SCPSE_09153_09168.bsp sclk_kernel sclk/cas00133.tsc time_kernel lsk/naif0009.tls instrument_kernel ik/cas_radar_v11.ti frame_kernel fk/cas_v39.tf planetary_constants_kernel pck/cpck08Jul2009.tpc solarsystem_ephemeris_kernel sp/090708R_SCPSE_09153_09168.bsp planet_ephemeris_kernel sp/090708R_SCPSE_09153_09168.bsp #----------------------------------------------------------------------------- # Ckernel Names # ckernel_directory - Directory where C-kernel files reside # If not present, fully qualified names must be used # ckernel - name of first ckernel file to load # ckernel_* - optional additional ckernel files to load # * is replaced by 1,2,3.. #----------------------------------------------------------------------------- ckernel_directory /home/ras/dat/naif/ck/ ckernel 09156_09161ra.bc #----------------------------------------------------------------------------- # Time Interval Specifications # Interval specificiations are epoch relative and consist of three associated # keywords (time_step_xx, start_time_xx, end_time_xx where xx is a string # identifying a particular interval). # time_step - The default time step to use # start_time - Default epoch relative starting time # end_time - Default epoch relative ending time #----------------------------------------------------------------------------- time_step 10 s start_time -540 min end_time 35 min #----------------------------------------------------------------------------- # Live Update Spice File Setup # live_update_spice_directory - Directory where updated Spice files reside # (except ckernels) If not present, fully qualified names must be used # live_update_tour_ephemeris - Live update SPICE file # The spacecraft ephemeris file # live_update_sclk_kernel - Live update SPICE file # sclk to UTC translation data # live_update_time_kernel - Live update SPICE file # leapseconds data # live_update_instrument_kernel - Live update SPICE file # field of view data for an instrument # live_update_frame_kernel - Live update SPICE file # instrument frame definitions # live_update_planetary_constants_kernel - Live update SPICE file # GM, radii etc for planets # live_update_solarsystem_ephemeris_kernel - Live update SPICE file # planet barycenters # live_update_planet_ephemeris_kernel - Live update SPICE file # ephemeris data for specific planet # live_update_merged_ckernel_port2 - Ckernel file to be used by # live-ivp-update program, generally considered old ckernel before # live ivp update #----------------------------------------------------------------------------- live_update_tour_ephemeris x live_update_sclk_kernel x live_update_time_kernel x live_update_instrument_kernel x live_update_frame_kernel x live_update_planetary_constants_kernel x live_update_solarsystem_ephemeris_kernel x live_update_planet_ephemeris_kernel x #----------------------------------------------------------------------------- # RMSS Constants and semi-fixed parameters # InstDensityNavErrors - Switch the usage of Navigation Errors # in InstructionDensity Routine # Valid values for: InstDensityNavErrors # on - Use nav errors, this is the normal setting # off - Don't use nav errors # Some small distant targets may need the off setting # CDS_Cmd_Delay - Time delay between time command in the PEF going to CDS # vs the RADAR execution of that command. # (Expected to be +1 second) # SoftPowerCycle - Default = enable to allow RMSS to power down if there # is a radiometer division between two Active modes # (If Disabled, RMSS will not power down until last active mode) # AutoGainCycles - When AutoGain is enabled or a FLTSW autogain # Feature boundary is encountered # RMSS should insert rapid copies of the instruction # to give AutoGain ability to step at the start # AutoRadCycles - When AutoRad is enabled # RMSS should insert rapid copies of the instruction # to give AutoRAD ability to step at the start # Calibration_Instruction_Method - RMSS insert calibraion mode # (rerouted,chirp, leakage, ant only) # These can be inserted in 1 of 4 different locations in the IEB timeline # 0 - Normal Calibration Insert: Between each mode change. # 1 - Lumped.Beginning: Gather all calibrations to be done and insert # block at first location only # 2 - Lumped.Ending: Gather all calibrations to be done and insert # block at last location # 3 - Lumped.both ends: Gather all calibrations to be done and insert # at beginning and a copy at the end # Max_Scat_Incidence_Used - (default 60) During Scatterometry RMSS will update instruction based on validtime upto normally 60 degress. # However if PDT designs go to higher incidence or to reduce FINs the user can adjust this value. # Calibration_SARH_ANT_Cycles - Allows user to state the number of Ant calibration cycles to be inserted for the calibrartion routines. # SlowCFSCompression - Percentage (integer: between 0-100) of the Slow_Cfs parameter that RMSS is allowed to compress in order to # reduce the number of Slow Field Instructions (SIN). # BpdGapAdjustPercentage - Percentage (integer: between 0-100) of the amount of the Burst Period that RMSS is allowed to # increase the BPD in order to reduce the gap between ILXes. (goes with Bpd_Adjust below) # Scat_Validtime_Adjust_For_Gaps - (enable or disable) If enabled, RMSS may decrease the VALIDTIME time value (Up to a limit) to # reduce gaps between instruction boundaries (This can be enabled/disabled based on mode) # Alth_Validtime_Adjust_For_Gaps - (enable or disable) see note above. # Sarh_Validtime_Adjust_For_Gaps - (enable or disable) see note above. # Sarl_Validtime_Adjust_For_Gaps - (enable or disable) see note above. # Scat_Bpd_Adjust_For_Gaps - (enable or disable) If enabled, RMSS may increase Burst Period (BPD) (Up to a limit) to reduce gaps # between instruction boundaries (This can be enabled/disabled based on mode) # Alth_Bpd_Adjust_For_Gaps - (enable or disable) see note above. # Sarh_Bpd_Adjust_For_Gaps - (enable or disable) see note above. # Sarl_Bpd_Adjust_For_Gaps - (enable or disable) see note above. # RMSS_UserInputFile_1 - Provide a wtk formatted file to overwrite any # RMSS create section of the IEB. # The User Input File will NOT overwrite Power or TNC instructions. # The first file must have the '1' extention, # if there are more this extenstion should be incremented #----------------------------------------------------------------------------- InstDensityNavErrors on CDS_Cmd_Delay 1 s AutoGainCycles 3 AutoRadCycles 4 Calibration_Instruction_Method 1 Max_Scat_Incidence_Used 75 Calibration_SARH_ANT_Cycles 1 SlowCFSCompression 2 BpdGapAdjustPercentage 8 Scat_Validtime_Adjust_For_Gaps enable Alth_Validtime_Adjust_For_Gaps enable Sarh_Validtime_Adjust_For_Gaps enable Sarl_Validtime_Adjust_For_Gaps enable Scat_Bpd_Adjust_For_Gaps enable Alth_Bpd_Adjust_For_Gaps enable Sarh_Bpd_Adjust_For_Gaps enable Sarl_Bpd_Adjust_For_Gaps enable RMSS_UserInputFile_1 t56_psiv_090330_eng.wtk #----------------------------------------------------------------------------- # RMSS Piece-wise constant profiles # scat_prf_number_points - number of thetai,prf pairs # scat_thetai_* - incidence angle ranges for corresponding prf # scat_prf_* - PRF value to use with the corresponding thetai # For thetai between thetai_1 and thetai_2, prf_1 is used. # For thetai above the final thetai_n, the final prf_n is used. # For off-target situations, the final prf_n is used. # dutycycle_limit_number_points - number of prf,dutycycle limit pairs # dutycycle_limit_prf_* - PRF value at or above this will be limited to # the corresponding duty cycle value. Limits applied in order so lowest # PRF values should be listed first. # PRF values between _prf_1 and _prf_2 are limited to _d_1 for dutycycle # These limits are only applied to scatterometer mode divisions # dutycycle_limit_d_* - duty cycle limit value for the corresponding PRF # The * is replaced by 1,2,3 ... #----------------------------------------------------------------------------- scat_prf_number_points 7 % Below apply only to scatterometer divisions dutycycle_limit_number_points 2 scat_thetai_1 0 deg scat_prf_1 1000 Hz dutycycle_limit_prf_1 0 Hz dutycycle_limit_d_1 0.75 scat_thetai_2 35 deg scat_prf_2 900 Hz dutycycle_limit_prf_2 10000 Hz dutycycle_limit_d_2 0.75 scat_thetai_3 43 deg scat_prf_3 800 Hz scat_thetai_4 48 deg scat_prf_4 700 Hz scat_thetai_5 51 deg scat_prf_5 600 Hz scat_thetai_6 54 deg scat_prf_6 500 Hz scat_thetai_7 60 deg scat_prf_7 500 Hz #----------------------------------------------------------------------------- # Radar Commanding Parameters # radar mode options: # sarh, sarl, altimeter, scatterometer, scatterometer_compressed, radiometer # Calibration source: # 0(normal), 1(antenna cal source), 2(noise diode), 3(resitive load) # 4(rerouted chirp),5(leakage),6(radiometer only),7(transmit only) # 8(auto gain) # baq: # 0(8-2 baq),1(8-1 baq), 2(8-0,no science data),3(ALTL compressed) # 4(8-4MSB), 5(8-8 straight), 6(ALTL),7(ALTH) # beam mask # 00000 : all beams disabled # 00001: beam 1 only # .. # 00100: beam 3 only # 11111: all beams only # Division keywords are identified by suffix letter _a, _b etc. # div_mode_* # div_start_time_* # div_end_time_* # div_time_step_* # div_bem_* # div_baq_* # div_csr_* # div_noise_bit_setting_* # div_bpd_* # div_dutycycle_* # div_prf* # div_tro_* # div_number_of_pulses_* # div_n_bursts_in_flight_* # div_percent_of_BW_* # div_auto_rad_* # div_rip_* # div_max_data_rate_* # div_interleave_flag_* # div_interleave_duration_* #----------------------------------------------------------------------------- %--------warmup---------------------- div_mode_a radiometer div_start_time_a -540 min div_end_time_a -290 min div_time_step_a 30 min div_bem_a 00100 div_baq_a 5 div_csr_a 6 div_noise_bit_setting_a 4 div_dutycycle_a 0.38 div_prf_a 1 KHz div_tro_a 0 div_number_of_pulses_a 8 div_n_bursts_in_flight_a 1 div_percent_of_BW_a 100 div_auto_rad_a on div_rip_a 34 ms div_max_data_rate_a 0.992 div_interleave_flag_a off div_interleave_duration_a 10 min %---------rad quicks--------------------- div_mode_b radiometer div_start_time_b -290 min div_end_time_b -288 min div_time_step_b 30 s div_bem_b 00100 div_baq_b 5 div_csr_b 6 div_noise_bit_setting_b 4 div_dutycycle_b 0.38 div_prf_b 1 KHz div_tro_b 0 div_number_of_pulses_b 8 div_n_bursts_in_flight_b 1 div_percent_of_BW_b 100 div_auto_rad_b on div_rip_b 34 ms div_max_data_rate_b 0.992 div_interleave_flag_b off div_interleave_duration_b 10 min %------------------------------ div_mode_c radiometer div_start_time_c -288 min div_end_time_c -122 min div_time_step_c 45 min div_bem_c 00100 div_baq_c 5 div_csr_c 6 div_noise_bit_setting_c 4 div_dutycycle_c 0.38 div_prf_c 1 KHz div_tro_c 0 div_number_of_pulses_c 8 div_n_bursts_in_flight_c 1 div_percent_of_BW_c 100 div_auto_rad_c on div_rip_c 34 ms div_max_data_rate_c 0.992 div_interleave_flag_c off div_interleave_duration_c 10 min %------------------------------ div_mode_d scatterometer div_start_time_d -122 min div_end_time_d -70 min div_time_step_d 6 s div_bem_d 00100 div_baq_d 5 div_csr_d 0 div_noise_bit_setting_d 4 div_dutycycle_d 0.7 div_prf_d 1200 Hz div_tro_d 6 div_number_of_pulses_d 8 div_n_bursts_in_flight_d 1 div_percent_of_BW_d 100 div_auto_rad_d on div_rip_d 34 ms div_max_data_rate_d 21 div_interleave_flag_d off div_interleave_duration_d 10 min %------------------------------ div_mode_e scatterometer div_start_time_e -70 min div_end_time_e -68.0 min div_time_step_e 18 s div_bem_e 00100 div_baq_e 0 div_csr_e 0 div_noise_bit_setting_e 4 div_dutycycle_e 0.6 div_prf_e 600 Hz div_tro_e 6 div_number_of_pulses_e 44 div_n_bursts_in_flight_e 1 div_percent_of_BW_e 100 div_auto_rad_e on div_rip_e 34 ms div_max_data_rate_e 67 div_interleave_flag_e off div_interleave_duration_e 10 min %------------------------------ div_mode_f scatterometer div_start_time_f -68 min div_end_time_f -66.0 min div_time_step_f 18 s div_bem_f 00100 div_baq_f 0 div_csr_f 0 div_noise_bit_setting_f 4 div_dutycycle_f 0.6 div_prf_f 800 Hz div_tro_f 6 div_number_of_pulses_f 60 div_n_bursts_in_flight_f 1 div_percent_of_BW_f 100 div_auto_rad_f on div_rip_f 34 ms div_max_data_rate_f 67 div_interleave_flag_f off div_interleave_duration_f 10 min %------------------------------ div_mode_g scatterometer div_start_time_g -66.0 min div_end_time_g -56.5 min div_time_step_g 18 s div_bem_g 00100 div_baq_g 0 div_csr_g 0 div_noise_bit_setting_g 4 div_dutycycle_g 0.6 div_prf_g 1100 Hz div_tro_g 6 div_number_of_pulses_g 80 div_n_bursts_in_flight_g 1 div_percent_of_BW_g 100 div_auto_rad_g on div_rip_g 34 ms div_max_data_rate_g 67 div_interleave_flag_g off div_interleave_duration_g 10 min %------------------------------ div_mode_h scatterometer div_start_time_h -56.5 min div_end_time_h -54.0 min div_time_step_h 18 s div_bem_h 00100 div_baq_h 0 div_csr_h 0 div_noise_bit_setting_h 4 div_dutycycle_h 0.6 div_prf_h 850 Hz div_tro_h 6 div_number_of_pulses_h 64 div_n_bursts_in_flight_h 1 div_percent_of_BW_h 100 div_auto_rad_h on div_rip_h 34 ms div_max_data_rate_h 67 div_interleave_flag_h off div_interleave_duration_h 10 min %------------------------------ div_mode_i scatterometer div_start_time_i -54.0 min div_end_time_i -52.5 min div_time_step_i 18 s div_bem_i 00100 div_baq_i 0 div_csr_i 0 div_noise_bit_setting_i 4 div_dutycycle_i 0.6 div_prf_i 600 Hz div_tro_i 6 div_number_of_pulses_i 44 div_n_bursts_in_flight_i 1 div_percent_of_BW_i 100 div_auto_rad_i on div_rip_i 34 ms div_max_data_rate_i 67 div_interleave_flag_i off div_interleave_duration_i 10 min %------------------------------ div_mode_j scatterometer div_start_time_j -52.5 min div_end_time_j -51.5 min div_time_step_j 18 s div_bem_j 00100 div_baq_j 0 div_csr_j 0 div_noise_bit_setting_j 4 div_dutycycle_j 0.6 div_prf_j 800 Hz div_tro_j 6 div_number_of_pulses_j 60 div_n_bursts_in_flight_j 1 div_percent_of_BW_j 100 div_auto_rad_j on div_rip_j 34 ms div_max_data_rate_j 67 div_interleave_flag_j off div_interleave_duration_j 10 min %------------------------------ div_mode_k scatterometer div_start_time_k -51.5 min div_end_time_k -49 min div_time_step_k 18 s div_bem_k 00100 div_baq_k 0 div_csr_k 0 div_noise_bit_setting_k 4 div_dutycycle_k 0.6 div_prf_k 1200 Hz div_tro_k 6 div_number_of_pulses_k 90 div_n_bursts_in_flight_k 1 div_percent_of_BW_k 100 div_auto_rad_k on div_rip_k 34 ms div_max_data_rate_k 67 div_interleave_flag_k off div_interleave_duration_k 10 min %------------------------------ div_mode_l scatterometer div_start_time_l -49 min div_end_time_l -45 min div_time_step_l 18 s div_bem_l 00100 div_baq_l 0 div_csr_l 0 div_noise_bit_setting_l 4 div_dutycycle_l 0.6 div_prf_l 1302 Hz div_tro_l 6 div_number_of_pulses_l 94 div_n_bursts_in_flight_l 1 div_percent_of_BW_l 100 div_auto_rad_l on div_rip_l 34 ms div_max_data_rate_l 70 div_interleave_flag_l off div_interleave_duration_l 10 min %------------------------------ div_mode_m scatterometer div_start_time_m -45 min div_end_time_m -44 min div_time_step_m 18 s div_bem_m 00100 div_baq_m 0 div_csr_m 0 div_noise_bit_setting_m 4 div_dutycycle_m 0.6 div_prf_m 1302 Hz div_tro_m 6 div_number_of_pulses_m 94 div_n_bursts_in_flight_m 1 div_percent_of_BW_m 100 div_auto_rad_m on div_rip_m 34 ms div_max_data_rate_m 70 div_interleave_flag_m off div_interleave_duration_m 10 min %------------------------------ div_mode_n scatterometer div_start_time_n -44 min div_end_time_n -42.5 min div_time_step_n 18 s div_bem_n 00100 div_baq_n 0 div_csr_n 0 div_noise_bit_setting_n 4 div_dutycycle_n 0.6 div_prf_n 1302 Hz div_tro_n 6 div_number_of_pulses_n 94 div_n_bursts_in_flight_n 1 div_percent_of_BW_n 100 div_auto_rad_n on div_rip_n 34 ms div_max_data_rate_n 70 div_interleave_flag_n off div_interleave_duration_n 10 min %------------------------------ div_mode_o sarl div_start_time_o -42.5 min div_end_time_o -30.3 min div_time_step_o 16 s div_bem_o 00100 div_baq_o 0 div_csr_o 0 div_noise_bit_setting_o 3.9 div_dutycycle_o 0.6 div_prf_o 2000 Hz div_tro_o 6 div_number_of_pulses_o 90 div_n_bursts_in_flight_o 1 div_percent_of_BW_o 100 div_auto_rad_o on div_rip_o 34 ms div_max_data_rate_o 100 div_interleave_flag_o off div_interleave_duration_o 10 min %------------------------------ div_mode_p altimeter div_start_time_p -30.3 min div_end_time_p -19.9 min div_time_step_p 16 s div_bem_p 00100 div_baq_p 7 div_csr_p 8 div_noise_bit_setting_p 2.3 div_dutycycle_p 0.73 div_prf_p 5000 Hz div_tro_p -6 div_number_of_pulses_p 21 div_n_bursts_in_flight_p 1 div_percent_of_BW_p 100 div_auto_rad_p on div_rip_p 34 ms div_max_data_rate_p 32 div_interleave_flag_p on div_interleave_duration_p 8 min %--------- on the turn--------------------- div_mode_q sarh div_start_time_q -19.9 min div_end_time_q -18.3 min div_time_step_q 10 s div_bem_q 00100 div_baq_q 0 div_csr_q 8 div_noise_bit_setting_q 3.4 div_dutycycle_q 0.7 div_prf_q 0 Hz div_tro_q 0 div_number_of_pulses_q 0 div_n_bursts_in_flight_q 1 div_percent_of_BW_q 100 div_auto_rad_q on div_rip_q 34 ms div_max_data_rate_q 50 div_interleave_flag_q off div_interleave_duration_q 10 min %------------------------------ div_mode_r sar_ping_pong div_start_time_r -18.3 min div_end_time_r -16 min div_time_step_r 10 s div_bem_r 11111 div_baq_r 0 div_csr_r 0 div_noise_bit_setting_r 3.4 div_dutycycle_r 0.7 div_prf_r 0 Hz div_tro_r 0 div_number_of_pulses_r 0 div_n_bursts_in_flight_r 1 div_percent_of_BW_r 100 div_auto_rad_r off div_rip_r 34 ms div_max_data_rate_r 236 div_interleave_flag_r off div_interleave_duration_r 10 min %------------------------------ div_mode_s sarh div_start_time_s -16 min div_end_time_s -2 min div_time_step_s 10 s div_bem_s 11111 div_baq_s 0 div_csr_s 8 div_noise_bit_setting_s 3.4 div_dutycycle_s 0.7 div_prf_s 0 KHz div_tro_s 0 div_number_of_pulses_s 0 div_n_bursts_in_flight_s 1 div_percent_of_BW_s 100 div_auto_rad_s off div_rip_s 34 ms div_max_data_rate_s 236 div_interleave_flag_s off div_interleave_duration_s 10 min %------------------------------ div_mode_t sarh div_start_time_t -2 min div_end_time_t 2 min div_time_step_t 10 s div_bem_t 11111 div_baq_t 0 div_csr_t 8 div_noise_bit_setting_t 3.4 div_dutycycle_t 0.7 div_prf_t 0 KHz div_tro_t 0 div_number_of_pulses_t 0 div_n_bursts_in_flight_t 1 div_percent_of_BW_t 98 div_auto_rad_t off div_rip_t 34 ms div_max_data_rate_t 236 div_interleave_flag_t off div_interleave_duration_t 10 min %------------------------------ div_mode_u sarh div_start_time_u 2 min div_end_time_u 16 min div_time_step_u 10 s div_bem_u 11111 div_baq_u 0 div_csr_u 8 div_noise_bit_setting_u 3.4 div_dutycycle_u 0.7 div_prf_u 0 KHz div_tro_u 0 div_number_of_pulses_u 0 div_n_bursts_in_flight_u 1 div_percent_of_BW_u 100 div_auto_rad_u off div_rip_u 34 ms div_max_data_rate_u 236 div_interleave_flag_u off div_interleave_duration_u 10 min %------------------------------ div_mode_v sar_ping_pong div_start_time_v 16 min div_end_time_v 18.3 min div_time_step_v 10 s div_bem_v 11111 div_baq_v 0 div_csr_v 0 div_noise_bit_setting_v 3.4 div_dutycycle_v 0.7 div_prf_v 0 Hz div_tro_v 0 div_number_of_pulses_v 0 div_n_bursts_in_flight_v 1 div_percent_of_BW_v 100 div_auto_rad_v off div_rip_v 34 ms div_max_data_rate_v 236 div_interleave_flag_v off div_interleave_duration_v 10 min %--------- on the turn--------------------- div_mode_w sarh div_start_time_w 18.3 min div_end_time_w 19.4 min div_time_step_w 10 s div_bem_w 00100 div_baq_w 0 div_csr_w 8 div_noise_bit_setting_w 3.4 div_dutycycle_w 0.7 div_prf_w 0 Hz div_tro_w 0 div_number_of_pulses_w 0 div_n_bursts_in_flight_w 1 div_percent_of_BW_w 100 div_auto_rad_w on div_rip_w 34 ms div_max_data_rate_w 50 div_interleave_flag_w off div_interleave_duration_w 10 min %----------------19.4 min 1164 ------- div_mode_x scatterometer div_start_time_x 1164 s div_end_time_x 1168 s div_time_step_x 10 s div_bem_x 00100 div_baq_x 5 div_csr_x 0 div_noise_bit_setting_x 4 div_dutycycle_x 0.5 div_prf_x 1200 Hz div_tro_x 2 div_number_of_pulses_x 4 div_n_bursts_in_flight_x 1 div_percent_of_BW_x 90 div_auto_rad_x off div_rip_x 34 ms div_max_data_rate_x 140 div_interleave_flag_x off div_interleave_duration_x 410 s %------------------------------ div_mode_y scatterometer div_start_time_y 1168 s div_end_time_y 1170 s div_time_step_y 10 s div_bem_y 00100 div_baq_y 5 div_csr_y 0 div_noise_bit_setting_y 4 div_dutycycle_y 0.73 div_prf_y 1000 Hz div_tro_y 6 div_number_of_pulses_y 1 div_n_bursts_in_flight_y 1 div_percent_of_BW_y 0 div_auto_rad_y off div_rip_y 34 ms div_max_data_rate_y 140 div_interleave_flag_y off div_interleave_duration_y 410 s %------------------------------ div_mode_z altimeter div_start_time_z 1170 s div_end_time_z 25.9 min div_time_step_z 22 s div_bem_z 00100 div_baq_z 7 div_csr_z 8 div_noise_bit_setting_z 2.3 div_dutycycle_z 0.73 div_prf_z 5000 Hz div_tro_z -6 div_number_of_pulses_z 21 div_n_bursts_in_flight_z 1 div_percent_of_BW_z 100 div_auto_rad_z on div_rip_z 34 ms div_max_data_rate_z 32 div_interleave_flag_z on div_interleave_duration_z 8 min %------------------------------ div_mode_{ scatterometer div_start_time_{ 25.9 min div_end_time_{ 26.7 min div_time_step_{ 18 s div_bem_{ 00100 div_baq_{ 0 div_csr_{ 0 div_noise_bit_setting_{ 4 div_dutycycle_{ 0.6 div_prf_{ 1200 Hz div_tro_{ 6 div_number_of_pulses_{ 50 div_n_bursts_in_flight_{ 1 div_percent_of_BW_{ 100 div_auto_rad_{ on div_rip_{ 34 ms div_max_data_rate_{ 50 div_interleave_flag_{ off div_interleave_duration_{ 10 min %------------------------------ div_mode_| radiometer div_start_time_| 26.7 min div_end_time_| 28 min div_time_step_| 1 min div_bem_| 00100 div_baq_| 5 div_csr_| 6 div_noise_bit_setting_| 4 div_dutycycle_| 0.38 div_prf_| 1 KHz div_tro_| 0 div_number_of_pulses_| 8 div_n_bursts_in_flight_| 1 div_percent_of_BW_| 100 div_auto_rad_| on div_rip_| 34 ms div_max_data_rate_| 0.992 div_interleave_flag_| off div_interleave_duration_| 10 min #----------------------------------------------------------------------------- # Special Chirp Start Frequency Selection # Make_csf_integer_multiple_of_prf -(this choice is used only for CW wave) If Yes(yes), chirp start frequency will be adjusted to be an integer multiple of prf if possible or minimize fractional part of csf/prf # Min_frequency_of_returned_CW_echo - when Make_csf_integer_multiple_of_prf is enabled, chirp start frequency will be scanned in such a way that echo location in the base band is larger than this value : suggested value -100 KHz # Max_frequency_of_returned_CW_echo - - when Make_csf_integer_multiple_of_prf is enabled, chirp start frequency will be scanned in such a way that echo location in the base band is smaller than this value: suggested value -20 KHz #----------------------------------------------------------------------------- %------------------------------ Make_csf_integer_multiple_of_prf Yes Min_frequency_of_returned_CW_echo -100 KHz Max_frequency_of_returned_CW_echo -20 KHz #----------------------------------------------------------------------------- # Parameters needed by dlap_generate # tracking_option - Specifies the general behavior of the spacecraft rotation # about the Y axis during SAR pointing. # Valid values for: tracking_option # target_center - Point -Z at the target spin axis. # If the incidence angle is zero, then this # simply means to point -Z at the target center. # target_isodoppler - Point -Z so as to minimize doppler variation in the # cross-track direction. # target_pitch_bias - Apply a rotation about spacecraft y-axis away from # isodoppler pointing. This option is used to increase # alongtrack coverage during Titan tour # target_contiguous_coverage - Point -Z so as to fan the 5 beams # perpendicular to the projected # motion of the 5 beams. # incidence_angle_offset - Change incidence angle profile from an ideal one # by adding a constant offset angle # set_azimuth_rotation - Used when tracking_option is set to target_center. # This keyword specifies the azimuth offset to use. # set_sc_z_rotation - Used when tracking_option is set to target_isodoppler # This keyword specifies an additional rotation w.r.t # sc z_axis after isodoppler location is set. # number_of_local_incidence_angle_changes - number of local incidence angle changes Each change requires 5 parameters # absence of this keyword means there is no local incidence angle modification # Valid values for: number_of_local_incidence_angle_changes # local_incidence_angle_offset_* -incidence angle bias # local_incidence_angle_tr1_* -start time from ideal pointing toward bias # local_incidence_angle_tr1_* -end of transition to local bias # local_incidence_angle_tr1_* -begining time from local bias toward ideal pointing # local_incidence_angle_tr1_* -end time to reach ideal pointing # angle_profile_option - Specifies the form of the incidence angle # profile to use # Valid values for: angle_profile_option # constant_incidence_angle - Use same incidence angle # throughout IVD interval # polynomial_fit - Use a polynomial profile fitted in the # least squares sense to points listed in # this config file. # sech_function - Use a hyperbolic secant function to model the incidence # angle variation. This function will fit the c/a incidence # angle, the residual incidence angle at high altitude, # and one mid point value. Special keywords below control # this model. #----------------------------------------------------------------------------- tracking_option target_pitch_bias incidence_angle_offset 0 deg set_azimuth_rotation 0 deg set_sc_z_rotation 0 deg angle_profile_option polynomial_fit #----------------------------------------------------------------------------- # When incidence angle profile is constant_incidence_angle # constant_incidence_angle - the constant incidence angle to use when # angle_profile_option is set to # constant_incidence_angle #----------------------------------------------------------------------------- constant_incidence_angle 10 deg #----------------------------------------------------------------------------- # When pitch bias option is chosen, the following parameters will be used # to compute spacecraft attitude # inbound_pitch_rate - Average inbound pitch bias rate: deg/min # outbound_pitch_rate - Average outbound pitch bias rate: deg/min # pitch_bias_outbound_end_time - End time of pitch bias. After this time, the # pointing moves back to isodoppler # pitch_bias_outbound_start_time - Start of pitch bias time for outbound track, # close to the closest approach time than # pitch_bias_outbound_end_time # pitch_bias_inbound_start_time - Start of pitch bias time for inbound track. # Close to the closest approach time than # pitch_bias_outbound_end_time # pitch_bias_inbound_end_time - End of pitch bias time for inbound track. # Before this time, the pointing is isodoppler #----------------------------------------------------------------------------- inbound_pitch_rate 0.6 deg/min outbound_pitch_rate -0.6 deg/min pitch_bias_outbound_end_time 30 min pitch_bias_outbound_start_time 10 min pitch_bias_inbound_start_time -10 min pitch_bias_inbound_end_time -30 min #----------------------------------------------------------------------------- # When angle profile option is polynomial_fit, # this incidence angle profile will be used # polynomial_power - the order of polynomial used to fit the incidence angle # profile points # number_of_altitude_incidenceAngle_variations - number of points to fit to a # polynomial profile # altitude* - altitude point to fit to a polynomial profile # incidenceAngle* - incidence angle point to fit to a polynomial profile #----------------------------------------------------------------------------- altitude1 950.001 km altitude11 2398.3 km altitude21 5245.61 km incidenceAngle1 35.1583 deg incidenceAngle11 16.7275 deg incidenceAngle21 12.4807 deg altitude10 2158.04 km incidenceAngle10 17.8359 deg altitude12 2650.72 km incidenceAngle12 16.1645 deg altitude13 2913.55 km incidenceAngle13 16.0165 deg altitude14 3185.33 km incidenceAngle14 16.0312 deg altitude15 3464.79 km incidenceAngle15 15.8233 deg altitude16 3750.88 km incidenceAngle16 14.8667 deg altitude17 4036.83 km incidenceAngle17 14.5654 deg altitude18 4333.05 km incidenceAngle18 13.548 deg altitude19 4633.61 km incidenceAngle19 13.5835 deg altitude2 967.326 km incidenceAngle2 34.7643 deg altitude20 4937.95 km incidenceAngle20 13.5603 deg altitude3 1019.17 km incidenceAngle3 33.6087 deg altitude4 1104.03 km incidenceAngle4 31.7946 deg altitude5 1219.65 km incidenceAngle5 29.4827 deg altitude6 1363.24 km incidenceAngle6 26.8769 deg altitude7 1531.81 km incidenceAngle7 24.2019 deg altitude8 1722.33 km incidenceAngle8 21.6812 deg altitude9 1931.94 km incidenceAngle9 19.511 deg polynomial_power 8 number_of_altitude_incidenceAngle_variations 21 #----------------------------------------------------------------------------- # When incidence angle Incidence angle sech profile parameters # when angle_profile_option is sech_function # angle = angle1 + 2*(angle2-angle1)/{exp( (x-x0)/a) + exp(-(x-x0)/a)} # angle1: residual incidence angle at high altitude # angle2: desired incidence angel at closest approach # a: this parameter will be calculated inside dlap_generate programs # and is used to obtain a desired incidence angle # at a mid altitude between closest approach (about 950 km) and # high altitude (> 4000 km) # this function will try to fit incidence angle at CA, residual incidence angle # at high altitude,and one mid point value between CA and high altitude # incidence_angle_at_lowest_altitude - for sech_function model # mid_altitude - for sech_function model # incidence_angle_at_mid_altitude - for sech_function_model # residual_incidence_angle_at_high_altitude - for sech_function model #----------------------------------------------------------------------------- incidence_angle_at_lowest_altitude 35 deg mid_altitude 2000 km incidence_angle_at_mid_altitude 20 deg residual_incidence_angle_at_high_altitude 0 deg #----------------------------------------------------------------------------- # Parameters needed to image a special targeting area specified by (lat, lon) # target_lat_lon_option - On or Off # target_isodoppler_pointing - On or Off # time_at_closest_range_to_target - Time w.r.t. epoch when sc makes a closest approach to the target (lat lon) # angle_at_closest_range_to_target - Incidence angle at time_at_closed_range_to_target for Isodoppler # start_target_lat_lon_tracking - Start time for tracking target_lat_lon before sc approaches targeted positin # end_target_lat_lon_tracking - End time for tracking target_lat_lon after sc passes targeted position # target_latitude - Used when tracking_option is set to target_isodopper_lat_lon # target_longitude - Used when tracking_option is se to target_isodoppler_lat_lon # off_centered_beam_time_lag - Time lag between beam3 and off-centered beam #----------------------------------------------------------------------------- target_lat_lon_option off target_isodoppler_pointing off time_at_closest_range_to_target -930.85 s angle_at_closest_range_to_target 18.0674 deg start_target_lat_lon_tracking -8 min end_target_lat_lon_tracking 8 min target_latitude -10.34 deg target_longitude 167.66 deg off_centered_beam_time_lag 2 min #----------------------------------------------------------------------------- # Parameters needed by ieb_param_generate # Time parameter will use start_time_ieb and end_time_ieb defined in # Time Specification # Some fixed parameters: long term duty cycle < 0.07 # ieb_file - Specifies ieb file containing time tagged slow/fast fields # start_time_ieb - If present, used to create ieb file # end_time_ieb - If present, used to create ieb file # time_step_ieb - If present, used to create ieb file # min_bpd # prf_profile_option - Specifies the form of the prf profile to use # Valid values for: prf_profile_option # constant_prf - Use same prf through IEB interval # polynomial_fit - Use a polynomial profile fitted in the least squares # senses to points listed in this config file # lookup_table - Not implemented yet #----------------------------------------------------------------------------- ieb_file t56_psiv_rmss_090330.ieb start_time_ieb -540 min end_time_ieb 35 min time_step_ieb 1 s prf_profile_option polynomial_fit #----------------------------------------------------------------------------- # When prf_profile_option is constant_prf, this value will be used # constant_prf_value - the constant prf value to use when prf profile # option is set to constant_prf #----------------------------------------------------------------------------- constant_prf_value 5000 Hz #----------------------------------------------------------------------------- # PRF profile to be used when prf_profile_option is polynomial_fit # time_prf_polynomial_power - the order of polynomial used to fit the the # prf profile points # number_of_time_prf_variations - number of points to fit to a polynomial # profile # time_prf* - time for prf # prf* - prf point to fit to a polynomial profile #----------------------------------------------------------------------------- % This prf profile is nominal low pass: prf1=5478.26 % modified to be 0.9*low altitude profile: prf1=4930.43 % for altitudes greater than 1200km use prf1=5200 time_prf1 -0 min time_prf11 -10 min time_prf21 -20 min prf1 5478.26 Hz prf11 4282.93 Hz prf21 2589.74 Hz time_prf10 -9 min prf10 4465.27 Hz time_prf12 -11 min prf12 4082.35 Hz time_prf13 -12 min prf13 3836.42 Hz time_prf14 -13 min prf14 3535.71 Hz time_prf15 -14 min prf15 3295.45 Hz time_prf16 -15 min prf16 3159.26 Hz time_prf17 -16 min prf17 2911.95 Hz time_prf18 -17 min prf18 2862.82 Hz time_prf19 -18 min prf19 2718.17 Hz time_prf2 -1 min prf2 5414.63 Hz time_prf20 -19 min prf20 2606.87 Hz time_prf3 -2 min prf3 5290.62 Hz time_prf4 -3 min prf4 5186.57 Hz time_prf5 -4 min prf5 5135.25 Hz time_prf6 -5 min prf6 5047.75 Hz time_prf7 -6 min prf7 4869.19 Hz time_prf8 -7 min prf8 4734.58 Hz time_prf9 -8 min prf9 4740 Hz time_prf_polynomial_power 4 number_of_time_prf_variations 21 #----------------------------------------------------------------------------- # dutycyle and altitude values # dutycycle_profile_option - Specifies the form of the dutycycle profile # to be used # Valid values for: dutycycle_profile_option # constant_dutycycle - Use constant dutycycle value in radar parameter block # polynomial_fit - Use a polymonial profile in the least squares sense # to points listed in this config file # It is very unlikely that we are going to use this option #----------------------------------------------------------------------------- dutycycle_profile_option constant_dutycycle #----------------------------------------------------------------------------- # Altitude-dependent dutycycle setup # when dutycycle profile option is polynomial_fit # alt_dutycycle_polynomial_power - the order of polynomial used to fit the # dutycycle profile points # number_of_altitude_dutycycle_variations - number of points to fit to # to a polynomial profile # alt_dutycycle1 - altitude point to fit a polynomial profile # dutycycle1 - dutycycle point to fit a polynomial profile # alt_dutycycle2 - altitude point to fit a polynomial profile # dutycycle2 - dutycycle point to fit a polynomial profile # alt_dutycycle3 - altitude point to fit a polynomial profile # dutycycle3 - dutycycle point to fit a polynomial profile # alt_dutycycle4 - altitude point to fit a polynomial profile # dutycycle4 - dutycycle point to fit a polynomial profile # alt_dutycycle5 - altitude point to fit a polynomial profile # dutycycle5 - dutycycle point to fit a polynomial profile #----------------------------------------------------------------------------- alt_dutycycle_polynomial_power 2 number_of_altitude_dutycycle_variations 3 alt_dutycycle1 1000 km dutycycle1 0.6 alt_dutycycle2 2000 km dutycycle2 0.65 alt_dutycycle3 4000 km dutycycle3 0.70 #----------------------------------------------------------------------------- # Parameters needed to set attenuator for scatterometer(ALTL) mode # cal_gaindB_altl - gain setting when calibration was performed # cal_radar_buffer_std_deviation_altl - standard deviation of radar buffer output (8-8 bits) # squared_deviation_of_system_noise_input_at_ALTL - measured squared deviation of 8-8 straight radar buffer data with the system noise and ALTL bandwidth # squared_deviation_of_system_noise_input_at_ALTH - measured squared deviation of 8-8 straight radar buffer data with the system noise and ALTH bandwidth # squared_deviation_of_system_noise_input_at_SARL - measured squared deviation of 8-8 straight radar buffer data with the system noise and SARL bandwidth # squared_deviation_of_system_noise_input_at_SARH - measured squared deviation of 8-8 straight radar buffer data with the system noise and SARH bandwidth #----------------------------------------------------------------------------- cal_gaindB_altl 8 cal_radar_buffer_std_deviation_altl 20.3 squared_deviation_of_system_noise_input_at_ALTL 1.74e18 s/J squared_deviation_of_system_noise_input_at_ALTH 1.38e18 s/J squared_deviation_of_system_noise_input_at_SARL 2.11e18 s/J squared_deviation_of_system_noise_input_at_SARH 1.48e18 s/J #----------------------------------------------------------------------------- # Antenna pattern configuration # beam_pattern_source - specifies how the beam pattern will be determined # Valid values for: beam_pattern_source # file - Read beam patterns from files specifed by subsequent keywords # sinc_model - Compute beam patterns from a sinc model using parameters # specified in subsequent keywords. # beam_azi_1 - Beam 1 azimuth beamwidth # beam_azi_2 - Beam 2 azimuth beamwidth # beam_azi_3 - Beam 3 azimuth beamwidth # beam_azi_4 - Beam 4 azimuth beamwidth # beam_azi_5 - Beam 5 azimuth beamwidth # beam_elev_1 - Beam 1 elevation beamwidth # beam_elev_2 - Beam 2 elevation beamwidth # beam_elev_3 - Beam 3 elevation beamwidth # beam_elev_4 - Beam 4 elevation beamwidth # beam_elev_5 - Beam 5 elevation beamwidth # beam_maxdB_gain1 - Beam 1 maximum gain (dB) # beam_maxdB_gain2 - Beam 2 maximum gain (dB) # beam_maxdB_gain3 - Beam 3 maximum gain (dB) # beam_maxdB_gain4 - Beam 4 maximum gain (dB) # beam_maxdB_gain5 - Beam 5 maximum gain (dB) # beam_mindB_gain - Beam gain value reported for out of range angles # beam_pattern_directory - full path to the directory containing beam patterns # beam_1_pattern_file - name of file containing pattern data for beam 1 # beam_2_pattern_file - name of file containing pattern data for beam 2 # beam_3_pattern_file - name of file containing pattern data for beam 3 # beam_4_pattern_file - name of file containing pattern data for beam 4 # beam_5_pattern_file - name of file containing pattern data for beam 5 #----------------------------------------------------------------------------- beam_pattern_source file beam_azi_1 0.35 deg beam_azi_2 0.35 deg beam_azi_3 0.35 deg beam_azi_4 0.35 deg beam_azi_5 0.35 deg beam_elev_1 1.35 deg beam_elev_2 1.35 deg beam_elev_3 0.35 deg beam_elev_4 1.35 deg beam_elev_5 1.35 deg beam_maxdB_gain1 44.2 beam_maxdB_gain2 44.2 beam_maxdB_gain3 50.7 beam_maxdB_gain4 44.2 beam_maxdB_gain5 44.2 beam_mindB_gain 20.0 beam_1_pattern_file /home/ras/dat/beam_patterns/beam1.042402.dat beam_2_pattern_file /home/ras/dat/beam_patterns/beam2.042402.dat beam_3_pattern_file /home/ras/dat/beam_patterns/beam3.042402.dat beam_4_pattern_file /home/ras/dat/beam_patterns/beam4.042402.dat beam_5_pattern_file /home/ras/dat/beam_patterns/beam5.042402.dat #----------------------------------------------------------------------------- # Back scattering model specification # Muhleman_backscatt_model_k1 - Muhleman model back scattering coefficient # Muhleman_backscatt_model_k2 - Muhleman model back scattering coefficient #----------------------------------------------------------------------------- Muhleman_backscatt_model_k1 0.0188 Muhleman_backscatt_model_k2 0.111 #----------------------------------------------------------------------------- # Parameters to be used by amb_geom_cal # time_step_sar - If present, used to run SAR simulation # start_time_sar - If present, used to run SAR simulation # end_time_sar - If present, used to run SAR simulation #----------------------------------------------------------------------------- time_step_sar 1 min start_time_sar -14 min end_time_sar 14 min #----------------------------------------------------------------------------- # Parameters to set up 4 ambiguity patches near the imaged area # number_of_dop_bins - Used by performance_cal , set number of dop bins inside # the process window # number_of_range_bins - Used by performance_cal, set number of range bins # inside the process window # number_of_dop_patches - Used by performance_cal, set number of dop patches # separated by prf from the process window # number_of_range_patches - Used by performance_cal, set number of range patches # separated by c * pri/2 from the process window #----------------------------------------------------------------------------- number_of_dop_bins 50 number_of_range_bins 200 #----------------------------------------------------------------------------- # Parameters to set up a global range-doppler grid # To calculate radar geometry factors based on range and doppler grids, # we need to set ranges of range and doppler # delta_doppler = +-2 * max_prf # delta_range = +- 2* (c * max_pri(=1/min_prf))/2 # then, frequency and range resolutions are determined by grid size N # frequency resolution of grid cells: 2* 2 * max_prf/grid # range resolution of grid cells: 2* 2 * (c * max_pri(1/min_prf)/2)/grid # max_prf and min_prf # Number_of_range_doppler_grid - Used by amb_geom_cal to set up global grid # whose range/doppler extents are determined by # ambiguity_search_max_prf -Used by amb_geom_cal to set extent of doppler axis # + - max_prf w.r.t. boresight doppler shift # ambiguity_search_min_prf - Used by amb_geom_cal to set extent of range axis # + - c *max_prf(/min_prf)/2 w.r.t. boresight range # calculate_mirror_ambiguity - Used by amb_geom_cal to calculate radar echo # from mirror location that has the same range/doppler # as the target location # Valid values for: calculate_mirror_ambiguity # Yes - calculate radar return echo from mirror location # No - do not consider radar return echo from mirror location #----------------------------------------------------------------------------- Number_of_range_doppler_grid 200 ambiguity_search_max_prf 6.0 KHz ambiguity_search_min_prf 2.0 KHz calculate_mirror_ambiguity Yes #----------------------------------------------------------------------------- # Parameters to be used by amb_param_scan # pulse_bandwidth_ratio # usable_area_search_max_prf - Set maximum prf # usable_area_search_min_prf - Set minimum prf # usable_area_number_of_prf_steps - Used by amb_param_scan, search usable area # using prf values from min_prf to max_prf # at an interval of # (max_prf - min_prf)/number_of_prf_steps # usable_area_search_max_pulsegate - Set maximum pulsegate # usable_area_search_min_pulsegate - Set minimum pulsegate # usable_area_number_of_pulsegate_steps - Used by amb_param_scan, search usable # area using pulsegate values # from min_pulsegate to max_pulsegate # at an interval of # (max_pulsegate - min_pulsegate)/number_of_pulsegate_steps #----------------------------------------------------------------------------- pulse_bandwidth_ratio 0.8 usable_area_search_max_prf 6.0 KHz usable_area_search_min_prf 2.0 KHz usable_area_number_of_prf_steps 41 usable_area_search_max_pulsegate 50 km usable_area_search_min_pulsegate 20 km usable_area_number_of_pulsegate_steps 6 #----------------------------------------------------------------------------- # Requirements for a pixel to be "usable" # signal_to_amb_ratiodB - Usable area should have a signal to amb ratio > + 14 dB # noise_equivalent_sigma0dB - Usable area should have a sigma0 < - 10 dB # min_oneway_gaindB_wrt_peak - Usable area should have a gain > -5 dB #----------------------------------------------------------------------------- signal_to_amb_ratiodB 5 noise_equivalent_sigma0dB 40 min_oneway_gaindB_wrt_peak -5 #----------------------------------------------------------------------------- # Radar Parameters # Pt - Transmitted power (46.2 W) # Tsys - System noise temperature (1000 K) # dutycycle_per_burst - long term dutycycle (< 7 %) # constant_dutycycle_value - constant dutycycle value to be used # carrier_frequency - Ku band frequency (13.78 GHz) # stalo_frequency - stable local oscillator frequency (10 MHz) #----------------------------------------------------------------------------- Pt 46.2 W Tsys 800 K dutycycle_per_burst 0.069 constant_dutycycle_value 0.7 carrier_frequency 13.77 GHz stalo_frequency 10 MHz #----------------------------------------------------------------------------- # PTS Options (Booleans) # COMPUTE_ECHO_AMPLITUDE - 1:= radar equation is employed, 0:= amplitude=1 # IDEAL_GAIN_SETTING - 1:= gain is set to fill ADC, 0:= IEB or CONFIG value used # IDEAL_TRACKING_ON - 1:= Boresight is centered in time and freq, 0: IEB or CONFIG params # SIMULATE_BAQ - 1/0 = ON/OFF # SIMULATE_QUANTIZATION - 1/0 = ON/OFF # SIMULATE_THERMAL_NOISE - 1/0 = ON/OFF # USE_CONFIG_BPD - 1:= Use BURST_PERIOD from config file # even if IEB mode enabled # ASSUME_FILTER_CENTERED - 1:= Do not use FILTER_START_FREQ_OFFSET, assume # anti-aliasing filter is centered in Nyquist usable # bandwidth for each mode # USE_RANDOM_PHASE_SHIFT - 1:= Applies a random phase shift (height on carrier # frequency scale) to point targets #----------------------------------------------------------------------------- ASSUME_FILTER_CENTERED 1 #----------------------------------------------------------------------------- # DOWNLINK Processing File Setup # ccsds_sci_file - Downlinked science only CCSDS file # egse_file_from_ccsds - Output of decode_ccsds program run # egse_filename - Downlinked binary file from spacecrfat # L1B_A_filename - Active mode file name(Scatterometry,Altimetry or SAR) # L1B_P_filename - Passive mode file name(Radiometer) # ras_filename - compressed BAQ threshold and RAW data # burst_ordered_ieblist - bursted ordered ieblist filename # L1I_filename - SAR Processor burst-by-burst output file # t_feed_filename - Filename for external temperature telemetry # E-2507.gph or NONE if not available # t_hga_filename - Filename for external temperature telemetry # E-2505.gph or NONE if not available # t_scwg_filename - Filename for external temperature telemetry # E-2503.gph or NONE if not available # Adjust_TFI_in_units_of_sclk - change TFI (active mode nominal value 1) # zero_range_time_delay_scatt - positive delay in generating pulse after # receiving command in scatt mode # zero_range_time_delay_alth - positive delay in generating pulse after # receiving command in alth mode # zero_range_time_delay_sarh - positive delay in generating pulse after # receiving command in sarh mode # zero_range_time_delay_sarl - positive delay in generating pulse after # receiving command in sarl mode # Show_sclk_adjust_message - when want to see all sclk correction, set 1 #----------------------------------------------------------------------------- ccsds_sci_file /home/ras/dat/tour/s50/t56/raw/t56_psiv_rmss_090330_001.sfdu egse_filename /home/ras/dat/tour/s50/t56/raw/t56_psiv_rmss_090330_001.08Jun09_1509 L1B_A_filename /home/ras/dat/tour/s50/t56/sarcentral/t56_reproc2.lbdr L1B_P_filename t56_reproc2.sbdr ras_filename /home/ras/dat/tour/s50/t56/reproc2/t56_ras.dat burst_ordered_ieblist t56_ieb.dat L1I_filename NONE t_feed_filename /home/ras/dat/tour/s50/t56/raw/anc1/E-2507.gph t_hga_filename /home/ras/dat/tour/s50/t56/raw/anc1/E-2505.gph t_scwg_filename /home/ras/dat/tour/s50/t56/raw/anc1/E-2503.gph Adjust_TFI_in_units_of_sclk 1 zero_range_time_delay_scatt 2e-6 s zero_range_time_delay_alth 6.35e-6 s zero_range_time_delay_sarh 10e-6 s zero_range_time_delay_sarl 10.5e-6 s #----------------------------------------------------------------------------- # Preprocessor Archiving (PDS) Parameters # BODP_PRODUCT_VERSION_ID - Version number of LBDR/SBDR/ABDR product for # PDS archiving # BODP_SOFTWARE_VERSION_ID - Version number of LBDR/SBDR/ABDR product for # PDS archiving # FLYBY_ID - Flyby name used in DESCRIPTION field in PDS label # MISSION_PHASE_NAME - Value for same keyword in PDS label # PRODUCER_FULL_NAME - Value for same keyword in PDS label # CHECK_PDS_STRING_LENGTHS - 1: Check that string values that are being # written to PDS labels conform to maximum # lengths specified by PDS standard. # 0: Disable checking. # If keyword not present, processor will behave # as if it had been set to "1." #----------------------------------------------------------------------------- BODP_PRODUCT_VERSION_ID 03 BODP_SOFTWARE_VERSION_ID V1.0 FLYBY_ID t56 MISSION_PHASE_NAME TOUR PRODUCER_FULL_NAME Inst_Lead_Charles_Elachi_contact_Bryan_Stiles #----------------------------------------------------------------------------- # SARProc I/O filenames and modes # CHECK_BURST_FILENAME - Filename for output MATLAB .m file if # CHECK_BURST_NO - Number of burst to output debug info from (starts with 1) # DATA_QUALITY_OVERRIDE_FILE - If this keyword is specified a file is used # to override the SAR processor nominal quality # checking for each burst. It can be used to force # the inclusion/exclusion of ranges of bursts. # SAR_PROC_SEGMENT_TYPE - Sets method of restricting sar processor including # FULL:= process all data # TIME_FROM_CLOSEST_APPROACH:= process time interval # SAB_COUNTER:= process sab_counter interval # LATLON:= process spatial region # SINGLE_BEAM_MODE - 1: Only one beam's data is processed # 0: All five beams are processed # SARPROC_BEAM_NUMBER - Beam to process if SINGLE_BEAM_MODE=1 # sar_annotation_file - Name of file to which burst by burst SAR processor # run-time output is directed. # SAR_PROC_AUTO_OVERWRITE_BIDR- 1: Automatically overwrite existing BIDR # output product files. # 0: If any of the BIDR output product files # exist, ask user whether to overwrite them. # Continue only if response is "y" or "Y." # If keyword not present, processor will behave # as if it had been set to "0." #----------------------------------------------------------------------------- SAR_PROC_SEGMENT_TYPE TIME_FROM_CLOSEST_APPROACH SINGLE_BEAM_MODE 0 SARPROC_BEAM_NUMBER 0 sar_annotation_file t56_reproc2_corramb_sarproc.ann #----------------------------------------------------------------------------- # SARProc Processing Parameters # DC_NULL_BINS - Size of filter for removing DC (in bins) # RANGE_REF_WINDOW_PARAM - Parameter for adjusting windowing performed # during range compression. Range is (0.0-1.0). # AZIMUTH_REF_WINDOW_PARAM - Parameter for adjusting windowing performed # during azimuth compression. Range is (0.0-1.0). # BIDR_LATLON_PAD_EACH_SIDE - Amount of pad applying to the four sides of # the BIDR image in order to avoid clipping of # data. # BIDR_PIXELS_PER_DEGREE - Resolution of BIDR image (nominally 256) # FULL_USABILITY_CALC_ENABLED - 1 set the processing window using a slow routine # which optimizes ambiguity isolation/window size # GAIN_CUTOFF_ENABLED - 1 enables nominal processing window selection method, # one-way antenna gain cut-off # GAIN_CUTOFF_POLYNOMIAL_ORDER - Order of polynominal in time used to compute # antenna gain cut-off threshold # GAIN_CUTOFF_BEAM_1_POLYNOMIAL_COEFF_* - Coefficients of gain cut-off # polynomial for beam 1. # GAIN_CUTOFF_BEAM_2_POLYNOMIAL_COEFF_* - # GAIN_CUTOFF_BEAM_3_POLYNOMIAL_COEFF_* - # GAIN_CUTOFF_BEAM_4_POLYNOMIAL_COEFF_* - # GAIN_CUTOFF_BEAM_5_POLYNOMIAL_COEFF_* - # INCIDENCE_ANGLE_CORRECTION_MODEL - Name of backscatter model used to produce # incidence angle corrected BIDR backplane # PULSE_SPREADING_IN_PRI - Coarse estimate of pulse spreading on the ground # used to determine size of overlapping window used # in range compression # SARPROC_NUM_LOOKS_REQUIRED - Minimum number of looks required to # produce a valid pixel in the BIDR image. #----------------------------------------------------------------------------- DC_NULL_BINS 5 GAIN_CUTOFF_BEAM_1_POLYNOMIAL_COEFF_0 5 GAIN_CUTOFF_BEAM_2_POLYNOMIAL_COEFF_0 5 GAIN_CUTOFF_BEAM_3_POLYNOMIAL_COEFF_0 5 GAIN_CUTOFF_BEAM_4_POLYNOMIAL_COEFF_0 5 GAIN_CUTOFF_BEAM_5_POLYNOMIAL_COEFF_0 5 RANGE_REF_WINDOW_PARAM 0.85 AZIMUTH_REF_WINDOW_PARAM 0.85 BIDR_LATLON_PAD_EACH_SIDE 2.0 deg BIDR_PIXELS_PER_DEGREE 256 FULL_USABILITY_CALC_ENABLED 1 GAIN_CUTOFF_ENABLED 0 GAIN_CUTOFF_POLYNOMIAL_ORDER 0 INCIDENCE_ANGLE_CORRECTION_MODEL HAGHAG PULSE_SPREADING_IN_PRI 1.0 SARPROC_NUM_LOOKS_REQUIRED 1 #----------------------------------------------------------------------------- # SARProc filename and PDS label construction keywords # BIDR_FILENAME_PREFIX - Prefix used to constuct BIDR filenames in initial runs # (does not conform to PDS filename format but allows # many trials to be run and kept track of during early # processing of data) # BIDR_PRODUCT_VERSION_ID - Specifies version number of BIDR product for PDS # archive # BIDR_SOFTWARE_VERSION_ID - Specifies version of sar processor software for # PDS archive # DATA_SET_MAP_PROJECTION_CATALOG - Specifies filename in PDS archive of .CAT # file which documents the oblique cylindrical # projection used in creating the BIDR map # SAR_PROC_USE_CONFIG_DATA_TAKE_NUMBER - 1: Use data take number from config # file; "data_take_number" must also be # set. # 0: Use data take number from LBDR file. # If keyword not present, processor will # behave as if it had been set to "0." #----------------------------------------------------------------------------- BIDR_FILENAME_PREFIX t56_reproc2_corramb_bidr BIDR_PRODUCT_VERSION_ID 03 BIDR_SOFTWARE_VERSION_ID V1.0 DATA_SET_MAP_PROJECTION_CATALOG DSMAP.CAT #----------------------------------------------------------------------------- # SARProc Sinc Interpolation coefficients # SINC_INTERP_FILTER_DOPPLER_BETA - Beta parameter for sinc interpolation in # the Doppler direction; used to adjust the # sinc kernel length based on the relative # bandwidth of the signal to the sampling # frequency. Values are in (0.0, 1.0], with # typical values ranging from 0.75 to 1.0. # SINC_INTERP_FILTER_DOPPLER_DEC_FACTOR - Decimation factor for sinc # interpolation in the Doppler # direction; sets fractional pixel # resolution of the interpolator. # Must be integer >= 1; typical value = # 1024. # SINC_INTERP_FILTER_DOPPLER_ENABLE_WEIGHTING - 1: Apply weighting function # for sinc interpolation in the Doppler # direction. # 0: Don't apply weighting function. # SINC_INTERP_FILTER_DOPPLER_PEDESTAL - Pedestal height for weighting function # for sinc interpolation in the Doppler # direction, with values in [0.0, 1.0]. # (1 = no weighting, 0 = Hanning) # SINC_INTERP_FILTER_DOPPLER_REL_LENGTH - Relative filter length for sinc # interpolation in the Doppler # direction; equals the number of # elements combined to produce an # interpolated sample. Must be an # integer >= 1; typical values are # 6, 8, or 16. # SINC_INTERP_FILTER_RANGE_BETA - Beta parameter for sinc interpolation in # the range direction; used to adjust the # sinc kernel length based on the relative # bandwidth of the signal to the sampling # frequency. Values are in (0.0, 1.0], with # typical values ranging from 0.75 to 1.0. # SINC_INTERP_FILTER_RANGE_DEC_FACTOR - Decimation factor for sinc # interpolation in the range direction; # sets fractional pixel resolution of # the interpolator. Must be integer >= # 1; typical value = 1024. # SINC_INTERP_FILTER_RANGE_ENABLE_WEIGHTING - 1: Apply weighting function # for sinc interpolation in the range # direction. # 0: Don't apply weighting function. # SINC_INTERP_FILTER_RANGE_PEDESTAL - Pedestal height for weighting function # for sinc interpolation in the range # direction, with values in [0.0, 1.0]. # (1 = no weighting, 0 = Hanning) # SINC_INTERP_FILTER_RANGE_REL_LENGTH - Relative filter length for sinc # interpolation in the range direction; # equals the number of elements combined # to produce an interpolated sample. # Must be an integer >= 1; typical values are 6, 8, or 16. #----------------------------------------------------------------------------- SINC_INTERP_FILTER_DOPPLER_BETA 1.0 SINC_INTERP_FILTER_DOPPLER_DEC_FACTOR 1024 SINC_INTERP_FILTER_DOPPLER_ENABLE_WEIGHTING 0 SINC_INTERP_FILTER_DOPPLER_PEDESTAL 0 SINC_INTERP_FILTER_DOPPLER_REL_LENGTH 8 SINC_INTERP_FILTER_RANGE_BETA 1.0 SINC_INTERP_FILTER_RANGE_DEC_FACTOR 1024 SINC_INTERP_FILTER_RANGE_ENABLE_WEIGHTING 0 SINC_INTERP_FILTER_RANGE_PEDESTAL 0 SINC_INTERP_FILTER_RANGE_REL_LENGTH 8 #----------------------------------------------------------------------------- # SARProc calibration constants # AZIMUTH_RESOLUTION_COEFFICIENT - Constant coefficient used to calculate SAR # effective resolution in the azimuth dimension. # RANGE_RESOLUTION_COEFFICIENT - Constant coefficient used to calculate SAR # effective resolution in the azimuth dimension. # ENABLE_DATA_DEPENDENT_CAL - 1 enables a debugging option which calibrates # the data by forcing no energy loss through the # range and azimuth compression stages # MAXIMAL_ONEWAY_GAIN_CORRECTION_IN_DB - maximal antenna gain correction applied # in SAR processor # X_FACTOR_CONSTANT_CORRECTION - Constant correction to Xfactor # XFACTOR_TIME_POLYNOMIAL_ORDER - Order of polynomial for time-varying Xfactor # correction # XFACTOR_TIME_POLYNOMIAL_COEFF_1 - First order time varying coefficient # XFACTOR_TIME_POLYNOMIAL_COEFF_2 - # XFACTOR_TIME_POLYNOMIAL_COEFF_3 - # XFACTOR_TIME_POLYNOMIAL_COEFF_4 - # X_FACTOR_BEAM_1 - Beam dependent Xfactor correction (Beam 1) ... # X_FACTOR_BEAM_2 - # X_FACTOR_BEAM_3 - # X_FACTOR_BEAM_4 - # X_FACTOR_BEAM_5 - #----------------------------------------------------------------------------- AZIMUTH_RESOLUTION_COEFFICIENT 0.87 RANGE_RESOLUTION_COEFFICIENT 0.87 ENABLE_DATA_DEPENDENT_CAL 0 MAXIMAL_ONEWAY_GAIN_CORRECTION_IN_DB 7.0 X_FACTOR_CONSTANT_CORRECTION 0.895777 XFACTOR_TIME_POLYNOMIAL_ORDER 0 X_FACTOR_BEAM_1 1.0 X_FACTOR_BEAM_2 1.0 X_FACTOR_BEAM_3 1.0 X_FACTOR_BEAM_4 1.0 X_FACTOR_BEAM_5 1.0 #----------------------------------------------------------------------------- # SARProc Options (Booleans) # PERFORM_SINGLE_BURST_CHECK - 1:= Output a Mfile for a selected burst # USE_HENSLEY_RANGE_COMPRESS - 1:= Use Scott Hensley' range compression method # 0:= Use an obsolete simplified method # USE_UPPER_BAND - 1: Range compress the upper half of the signal spectrum. # 0: Range compress the lower half of the signal spectrum. # So far as I know this should always be 0. # SARPROC_USE_LINEAR_CHIRP - 1: Use a linear chirp for range compression # 0: Use the more exact form of the stepped chirp # which was transmitted # PROC_SAR_MODE_ONLY - 1: Process only SARH or SARL data # 0: Process all data as if it were SAR # STRIP_PROC_ON - 1 turns on geolocation processing # AZIMUTH_RANGE_ORTHOGONALIZATION_ON - 1 turns on range dependent doppler shifting # for use in azimuth compression # AZIMUTH_DERAMP_PROCESSING_ON - 1 turns on deramp processing during azimuth # compression # SAR_CALIBRATION_ON - 1 turns on calibration of SAR data # REMOVE_DOPPLER_PHASE_RAMP - 1 turns on data dependent method for removing # phase ramps from compressed data # SARPROC_OUTPUT_SCATTEROMETER_INFO - 1 turns on an output of a simplified estimate # of the real aperture backscatter to the # LBDR file for debugging purposes. # USE_OBLIQUE_CYLINDRICAL - 1 turns on oblique clyndrical map projection. # USE_SINC_INTERPOLATION - 1:Sinc Interpolation 0:= Nearest neighbor #----------------------------------------------------------------------------- PERFORM_SINGLE_BURST_CHECK 0 USE_UPPER_BAND 0 SARPROC_USE_LINEAR_CHIRP 0 PROC_SAR_MODE_ONLY 1 STRIP_PROC_ON 1 AZIMUTH_RANGE_ORTHOGONALIZATION_ON 0 AZIMUTH_DERAMP_PROCESSING_ON 0 SAR_CALIBRATION_ON 1 REMOVE_DOPPLER_PHASE_RAMP 0 SARPROC_OUTPUT_SCATTEROMETER_INFO 1 USE_OBLIQUE_CYLINDRICAL 1 USE_SINC_INTERPOLATION 1 #----------------------------------------------------------------------------- # Parameters for ESTimation of Range and Doppler (ESTRD) a data # analysis technique used in the SAR processor to center the # gain patterns of the various antenna beams in the absense of accurate # ephemeris and pointing information # SET_DOPPLER_CENTROID - Turn on/off (0/1) ESTRD a data driven technique for # aligning beam gain patterns in doppler and range # dimensions when using inaccurate s/c ephemeris and # pointing. # DOPPLER_CENTROID_POLYNOMIAL_ORDER - Order of polynomial used to compute # doppler offset when ESTRD is employed # DOPPLER_CENTROID_MEAN - Mean doppler centroid offset, used by ESTRD algorithm # DOPPLER_CENTROID_STD - Standard deviation of the doppler centroid offset, # used by ESTRD algorithm # DOPPLER_CENTROID_BEAM_1_POLYNOMIAL_COEFF_* - Coefficients of polynomial in time # used to compute doppler offset # when ESTRD is employed for Beam 1. # DOPPLER_CENTROID_BEAM_2_POLYNOMIAL_COEFF_* - # DOPPLER_CENTROID_BEAM_3_POLYNOMIAL_COEFF_* - # DOPPLER_CENTROID_BEAM_4_POLYNOMIAL_COEFF_* - # DOPPLER_CENTROID_BEAM_5_POLYNOMIAL_COEFF_* - # RANGE_CENTROID_POLYNOMIAL_ORDER - Order of polynomial used to compute # range offset when ESTRD is employed # RANGE_CENTROID_MEAN - Mean range centroid offset, used by ESTRD algorithm # RANGE_CENTROID_STD - Standard deviation of the range centroid offset, # used by ESTRD algorithm # RANGE_CENTROID_BEAM_1_POLYNOMIAL_COEFF_* - Coefficients of polynomial in time # used to compute range offset # when ESTRD is employed for Beam 1. # RANGE_CENTROID_BEAM_2_POLYNOMIAL_COEFF_* - # RANGE_CENTROID_BEAM_3_POLYNOMIAL_COEFF_* - # RANGE_CENTROID_BEAM_4_POLYNOMIAL_COEFF_* - # RANGE_CENTROID_BEAM_5_POLYNOMIAL_COEFF_* - # ESTRD_TIME_MEAN - Mean time from closest approach, used by ESTRD algorithm # ESTRD_TIME_STD - Standard deviation of time from closest approach, # used by ESTRD algorithm #----------------------------------------------------------------------------- DOPPLER_CENTROID_BEAM_1_POLYNOMIAL_COEFF_0 0.098934759928532275963 DOPPLER_CENTROID_BEAM_1_POLYNOMIAL_COEFF_10 7.3474285389267892654 DOPPLER_CENTROID_BEAM_2_POLYNOMIAL_COEFF_0 0.098934759928532275963 DOPPLER_CENTROID_BEAM_2_POLYNOMIAL_COEFF_10 7.3474285389267892654 DOPPLER_CENTROID_BEAM_3_POLYNOMIAL_COEFF_0 0.098934759928532275963 DOPPLER_CENTROID_BEAM_3_POLYNOMIAL_COEFF_10 7.3474285389267892654 DOPPLER_CENTROID_BEAM_4_POLYNOMIAL_COEFF_0 0.098934759928532275963 DOPPLER_CENTROID_BEAM_4_POLYNOMIAL_COEFF_10 7.3474285389267892654 DOPPLER_CENTROID_BEAM_5_POLYNOMIAL_COEFF_0 0.098934759928532275963 DOPPLER_CENTROID_BEAM_5_POLYNOMIAL_COEFF_10 7.3474285389267892654 RANGE_CENTROID_BEAM_1_POLYNOMIAL_COEFF_0 -0.67510692674670413904 RANGE_CENTROID_BEAM_1_POLYNOMIAL_COEFF_10 -1.8267322716315890219 RANGE_CENTROID_BEAM_2_POLYNOMIAL_COEFF_0 -0.67510692674670413904 RANGE_CENTROID_BEAM_2_POLYNOMIAL_COEFF_10 -1.8267322716315890219 RANGE_CENTROID_BEAM_3_POLYNOMIAL_COEFF_0 -0.67510692674670413904 RANGE_CENTROID_BEAM_3_POLYNOMIAL_COEFF_10 -1.8267322716315890219 RANGE_CENTROID_BEAM_4_POLYNOMIAL_COEFF_0 -0.67510692674670413904 RANGE_CENTROID_BEAM_4_POLYNOMIAL_COEFF_10 -1.8267322716315890219 RANGE_CENTROID_BEAM_5_POLYNOMIAL_COEFF_0 -0.67510692674670413904 RANGE_CENTROID_BEAM_5_POLYNOMIAL_COEFF_10 -1.8267322716315890219 DOPPLER_CENTROID_BEAM_1_POLYNOMIAL_COEFF_1 -0.9368423032773296466 DOPPLER_CENTROID_BEAM_1_POLYNOMIAL_COEFF_11 4.4489416359984614857 DOPPLER_CENTROID_BEAM_2_POLYNOMIAL_COEFF_1 -0.9368423032773296466 DOPPLER_CENTROID_BEAM_2_POLYNOMIAL_COEFF_11 4.4489416359984614857 DOPPLER_CENTROID_BEAM_3_POLYNOMIAL_COEFF_1 -0.9368423032773296466 DOPPLER_CENTROID_BEAM_3_POLYNOMIAL_COEFF_11 4.4489416359984614857 DOPPLER_CENTROID_BEAM_4_POLYNOMIAL_COEFF_1 -0.9368423032773296466 DOPPLER_CENTROID_BEAM_4_POLYNOMIAL_COEFF_11 4.4489416359984614857 DOPPLER_CENTROID_BEAM_5_POLYNOMIAL_COEFF_1 -0.9368423032773296466 DOPPLER_CENTROID_BEAM_5_POLYNOMIAL_COEFF_11 4.4489416359984614857 RANGE_CENTROID_BEAM_1_POLYNOMIAL_COEFF_1 -1.8627021851353458004 RANGE_CENTROID_BEAM_1_POLYNOMIAL_COEFF_11 10.491517821420131895 RANGE_CENTROID_BEAM_2_POLYNOMIAL_COEFF_1 -1.8627021851353458004 RANGE_CENTROID_BEAM_2_POLYNOMIAL_COEFF_11 10.491517821420131895 RANGE_CENTROID_BEAM_3_POLYNOMIAL_COEFF_1 -1.8627021851353458004 RANGE_CENTROID_BEAM_3_POLYNOMIAL_COEFF_11 10.491517821420131895 RANGE_CENTROID_BEAM_4_POLYNOMIAL_COEFF_1 -1.8627021851353458004 RANGE_CENTROID_BEAM_4_POLYNOMIAL_COEFF_11 10.491517821420131895 RANGE_CENTROID_BEAM_5_POLYNOMIAL_COEFF_1 -1.8627021851353458004 RANGE_CENTROID_BEAM_5_POLYNOMIAL_COEFF_11 10.491517821420131895 DOPPLER_CENTROID_BEAM_1_POLYNOMIAL_COEFF_12 -1.4521971097585613109 DOPPLER_CENTROID_BEAM_2_POLYNOMIAL_COEFF_12 -1.4521971097585613109 DOPPLER_CENTROID_BEAM_3_POLYNOMIAL_COEFF_12 -1.4521971097585613109 DOPPLER_CENTROID_BEAM_4_POLYNOMIAL_COEFF_12 -1.4521971097585613109 DOPPLER_CENTROID_BEAM_5_POLYNOMIAL_COEFF_12 -1.4521971097585613109 RANGE_CENTROID_BEAM_1_POLYNOMIAL_COEFF_12 0.33324041746387988994 RANGE_CENTROID_BEAM_2_POLYNOMIAL_COEFF_12 0.33324041746387988994 RANGE_CENTROID_BEAM_3_POLYNOMIAL_COEFF_12 0.33324041746387988994 RANGE_CENTROID_BEAM_4_POLYNOMIAL_COEFF_12 0.33324041746387988994 RANGE_CENTROID_BEAM_5_POLYNOMIAL_COEFF_12 0.33324041746387988994 DOPPLER_CENTROID_BEAM_1_POLYNOMIAL_COEFF_13 -0.66892189577171845549 DOPPLER_CENTROID_BEAM_2_POLYNOMIAL_COEFF_13 -0.66892189577171845549 DOPPLER_CENTROID_BEAM_3_POLYNOMIAL_COEFF_13 -0.66892189577171845549 DOPPLER_CENTROID_BEAM_4_POLYNOMIAL_COEFF_13 -0.66892189577171845549 DOPPLER_CENTROID_BEAM_5_POLYNOMIAL_COEFF_13 -0.66892189577171845549 RANGE_CENTROID_BEAM_1_POLYNOMIAL_COEFF_13 -1.7849868881475998705 RANGE_CENTROID_BEAM_2_POLYNOMIAL_COEFF_13 -1.7849868881475998705 RANGE_CENTROID_BEAM_3_POLYNOMIAL_COEFF_13 -1.7849868881475998705 RANGE_CENTROID_BEAM_4_POLYNOMIAL_COEFF_13 -1.7849868881475998705 RANGE_CENTROID_BEAM_5_POLYNOMIAL_COEFF_13 -1.7849868881475998705 DOPPLER_CENTROID_BEAM_1_POLYNOMIAL_COEFF_14 0.11195189674480240938 DOPPLER_CENTROID_BEAM_2_POLYNOMIAL_COEFF_14 0.11195189674480240938 DOPPLER_CENTROID_BEAM_3_POLYNOMIAL_COEFF_14 0.11195189674480240938 DOPPLER_CENTROID_BEAM_4_POLYNOMIAL_COEFF_14 0.11195189674480240938 DOPPLER_CENTROID_BEAM_5_POLYNOMIAL_COEFF_14 0.11195189674480240938 RANGE_CENTROID_BEAM_1_POLYNOMIAL_COEFF_14 -0.022275469255198229734 RANGE_CENTROID_BEAM_2_POLYNOMIAL_COEFF_14 -0.022275469255198229734 RANGE_CENTROID_BEAM_3_POLYNOMIAL_COEFF_14 -0.022275469255198229734 RANGE_CENTROID_BEAM_4_POLYNOMIAL_COEFF_14 -0.022275469255198229734 RANGE_CENTROID_BEAM_5_POLYNOMIAL_COEFF_14 -0.022275469255198229734 DOPPLER_CENTROID_BEAM_1_POLYNOMIAL_COEFF_15 0.040439618254277290288 DOPPLER_CENTROID_BEAM_2_POLYNOMIAL_COEFF_15 0.040439618254277290288 DOPPLER_CENTROID_BEAM_3_POLYNOMIAL_COEFF_15 0.040439618254277290288 DOPPLER_CENTROID_BEAM_4_POLYNOMIAL_COEFF_15 0.040439618254277290288 DOPPLER_CENTROID_BEAM_5_POLYNOMIAL_COEFF_15 0.040439618254277290288 RANGE_CENTROID_BEAM_1_POLYNOMIAL_COEFF_15 0.12216347963181961589 RANGE_CENTROID_BEAM_2_POLYNOMIAL_COEFF_15 0.12216347963181961589 RANGE_CENTROID_BEAM_3_POLYNOMIAL_COEFF_15 0.12216347963181961589 RANGE_CENTROID_BEAM_4_POLYNOMIAL_COEFF_15 0.12216347963181961589 RANGE_CENTROID_BEAM_5_POLYNOMIAL_COEFF_15 0.12216347963181961589 DOPPLER_CENTROID_BEAM_1_POLYNOMIAL_COEFF_2 2.1257986657182370571 DOPPLER_CENTROID_BEAM_2_POLYNOMIAL_COEFF_2 2.1257986657182370571 DOPPLER_CENTROID_BEAM_3_POLYNOMIAL_COEFF_2 2.1257986657182370571 DOPPLER_CENTROID_BEAM_4_POLYNOMIAL_COEFF_2 2.1257986657182370571 DOPPLER_CENTROID_BEAM_5_POLYNOMIAL_COEFF_2 2.1257986657182370571 RANGE_CENTROID_BEAM_1_POLYNOMIAL_COEFF_2 2.9445869109808082698 RANGE_CENTROID_BEAM_2_POLYNOMIAL_COEFF_2 2.9445869109808082698 RANGE_CENTROID_BEAM_3_POLYNOMIAL_COEFF_2 2.9445869109808082698 RANGE_CENTROID_BEAM_4_POLYNOMIAL_COEFF_2 2.9445869109808082698 RANGE_CENTROID_BEAM_5_POLYNOMIAL_COEFF_2 2.9445869109808082698 DOPPLER_CENTROID_BEAM_1_POLYNOMIAL_COEFF_3 10.734521082693465388 DOPPLER_CENTROID_BEAM_2_POLYNOMIAL_COEFF_3 10.734521082693465388 DOPPLER_CENTROID_BEAM_3_POLYNOMIAL_COEFF_3 10.734521082693465388 DOPPLER_CENTROID_BEAM_4_POLYNOMIAL_COEFF_3 10.734521082693465388 DOPPLER_CENTROID_BEAM_5_POLYNOMIAL_COEFF_3 10.734521082693465388 RANGE_CENTROID_BEAM_1_POLYNOMIAL_COEFF_3 17.065063804003081316 RANGE_CENTROID_BEAM_2_POLYNOMIAL_COEFF_3 17.065063804003081316 RANGE_CENTROID_BEAM_3_POLYNOMIAL_COEFF_3 17.065063804003081316 RANGE_CENTROID_BEAM_4_POLYNOMIAL_COEFF_3 17.065063804003081316 RANGE_CENTROID_BEAM_5_POLYNOMIAL_COEFF_3 17.065063804003081316 DOPPLER_CENTROID_BEAM_1_POLYNOMIAL_COEFF_4 -12.947833108090499366 DOPPLER_CENTROID_BEAM_2_POLYNOMIAL_COEFF_4 -12.947833108090499366 DOPPLER_CENTROID_BEAM_3_POLYNOMIAL_COEFF_4 -12.947833108090499366 DOPPLER_CENTROID_BEAM_4_POLYNOMIAL_COEFF_4 -12.947833108090499366 DOPPLER_CENTROID_BEAM_5_POLYNOMIAL_COEFF_4 -12.947833108090499366 RANGE_CENTROID_BEAM_1_POLYNOMIAL_COEFF_4 -1.5496333076831172448 RANGE_CENTROID_BEAM_2_POLYNOMIAL_COEFF_4 -1.5496333076831172448 RANGE_CENTROID_BEAM_3_POLYNOMIAL_COEFF_4 -1.5496333076831172448 RANGE_CENTROID_BEAM_4_POLYNOMIAL_COEFF_4 -1.5496333076831172448 RANGE_CENTROID_BEAM_5_POLYNOMIAL_COEFF_4 -1.5496333076831172448 DOPPLER_CENTROID_BEAM_1_POLYNOMIAL_COEFF_5 -26.559304002772446296 DOPPLER_CENTROID_BEAM_2_POLYNOMIAL_COEFF_5 -26.559304002772446296 DOPPLER_CENTROID_BEAM_3_POLYNOMIAL_COEFF_5 -26.559304002772446296 DOPPLER_CENTROID_BEAM_4_POLYNOMIAL_COEFF_5 -26.559304002772446296 DOPPLER_CENTROID_BEAM_5_POLYNOMIAL_COEFF_5 -26.559304002772446296 RANGE_CENTROID_BEAM_1_POLYNOMIAL_COEFF_5 -43.564602215029083254 RANGE_CENTROID_BEAM_2_POLYNOMIAL_COEFF_5 -43.564602215029083254 RANGE_CENTROID_BEAM_3_POLYNOMIAL_COEFF_5 -43.564602215029083254 RANGE_CENTROID_BEAM_4_POLYNOMIAL_COEFF_5 -43.564602215029083254 RANGE_CENTROID_BEAM_5_POLYNOMIAL_COEFF_5 -43.564602215029083254 DOPPLER_CENTROID_BEAM_1_POLYNOMIAL_COEFF_6 22.817486327678171421 DOPPLER_CENTROID_BEAM_2_POLYNOMIAL_COEFF_6 22.817486327678171421 DOPPLER_CENTROID_BEAM_3_POLYNOMIAL_COEFF_6 22.817486327678171421 DOPPLER_CENTROID_BEAM_4_POLYNOMIAL_COEFF_6 22.817486327678171421 DOPPLER_CENTROID_BEAM_5_POLYNOMIAL_COEFF_6 22.817486327678171421 RANGE_CENTROID_BEAM_1_POLYNOMIAL_COEFF_6 -3.482254748967774205 RANGE_CENTROID_BEAM_2_POLYNOMIAL_COEFF_6 -3.482254748967774205 RANGE_CENTROID_BEAM_3_POLYNOMIAL_COEFF_6 -3.482254748967774205 RANGE_CENTROID_BEAM_4_POLYNOMIAL_COEFF_6 -3.482254748967774205 RANGE_CENTROID_BEAM_5_POLYNOMIAL_COEFF_6 -3.482254748967774205 DOPPLER_CENTROID_BEAM_1_POLYNOMIAL_COEFF_7 27.982362744245055097 DOPPLER_CENTROID_BEAM_2_POLYNOMIAL_COEFF_7 27.982362744245055097 DOPPLER_CENTROID_BEAM_3_POLYNOMIAL_COEFF_7 27.982362744245055097 DOPPLER_CENTROID_BEAM_4_POLYNOMIAL_COEFF_7 27.982362744245055097 DOPPLER_CENTROID_BEAM_5_POLYNOMIAL_COEFF_7 27.982362744245055097 RANGE_CENTROID_BEAM_1_POLYNOMIAL_COEFF_7 51.416968717678059875 RANGE_CENTROID_BEAM_2_POLYNOMIAL_COEFF_7 51.416968717678059875 RANGE_CENTROID_BEAM_3_POLYNOMIAL_COEFF_7 51.416968717678059875 RANGE_CENTROID_BEAM_4_POLYNOMIAL_COEFF_7 51.416968717678059875 RANGE_CENTROID_BEAM_5_POLYNOMIAL_COEFF_7 51.416968717678059875 DOPPLER_CENTROID_BEAM_1_POLYNOMIAL_COEFF_8 -18.240077147225520093 DOPPLER_CENTROID_BEAM_2_POLYNOMIAL_COEFF_8 -18.240077147225520093 DOPPLER_CENTROID_BEAM_3_POLYNOMIAL_COEFF_8 -18.240077147225520093 DOPPLER_CENTROID_BEAM_4_POLYNOMIAL_COEFF_8 -18.240077147225520093 DOPPLER_CENTROID_BEAM_5_POLYNOMIAL_COEFF_8 -18.240077147225520093 RANGE_CENTROID_BEAM_1_POLYNOMIAL_COEFF_8 4.3254755503390036608 RANGE_CENTROID_BEAM_2_POLYNOMIAL_COEFF_8 4.3254755503390036608 RANGE_CENTROID_BEAM_3_POLYNOMIAL_COEFF_8 4.3254755503390036608 RANGE_CENTROID_BEAM_4_POLYNOMIAL_COEFF_8 4.3254755503390036608 RANGE_CENTROID_BEAM_5_POLYNOMIAL_COEFF_8 4.3254755503390036608 DOPPLER_CENTROID_BEAM_1_POLYNOMIAL_COEFF_9 -15.181874132687072532 DOPPLER_CENTROID_BEAM_2_POLYNOMIAL_COEFF_9 -15.181874132687072532 DOPPLER_CENTROID_BEAM_3_POLYNOMIAL_COEFF_9 -15.181874132687072532 DOPPLER_CENTROID_BEAM_4_POLYNOMIAL_COEFF_9 -15.181874132687072532 DOPPLER_CENTROID_BEAM_5_POLYNOMIAL_COEFF_9 -15.181874132687072532 RANGE_CENTROID_BEAM_1_POLYNOMIAL_COEFF_9 -31.608084240252452446 RANGE_CENTROID_BEAM_2_POLYNOMIAL_COEFF_9 -31.608084240252452446 RANGE_CENTROID_BEAM_3_POLYNOMIAL_COEFF_9 -31.608084240252452446 RANGE_CENTROID_BEAM_4_POLYNOMIAL_COEFF_9 -31.608084240252452446 RANGE_CENTROID_BEAM_5_POLYNOMIAL_COEFF_9 -31.608084240252452446 SET_DOPPLER_CENTROID 1 DOPPLER_CENTROID_POLYNOMIAL_ORDER 15 DOPPLER_CENTROID_MEAN 27.37483301 Hz DOPPLER_CENTROID_STD 152.7421551 Hz RANGE_CENTROID_POLYNOMIAL_ORDER 15 RANGE_CENTROID_MEAN 0.2095635437 km RANGE_CENTROID_STD 0.3561619479 km ESTRD_TIME_MEAN 6.968163835 s ESTRD_TIME_STD 558.348833 s #----------------------------------------------------------------------------- # GENERATE_GEOMETRY_FILE keywords # intermediate_geometry_file - File containing geometry arrays used to speedup # geometry calculations currently used by sar_proc, # point_target_sim, and l0_l1b. Created by # generate_geometry_file # geometry_time_step - Time step used to create geometry file. #----------------------------------------------------------------------------- intermediate_geometry_file /home/ras/dat/tour/s50/t56/geom/t56_reproc2.gf #----------------------------------------------------------------------------- # DEBUGINFO debugging and warning keywords # debug_filename - Filename to write debugging info # debug_routine_name_1 - first routine to debug ... # debug_routine_name_2 - # debug_routine_name_3 - # debug_level_1 - debugging level for first routine # debug_level_2 - # debug_level_3 - # ENABLE_ALL_WARNINGS - turns on/off (1/0) verbose warning messages #----------------------------------------------------------------------------- debug_filename sarproc.dbg debug_routine_name_1 main debug_level_1 1 ENABLE_ALL_WARNINGS 0 #----------------------------------------------------------------------------- # Radiometer Processor Parameters # Number_of_targets - Number of targets for cruise or tour sequence # target_1 - Extra target in addition to main target set by target_keyword # cold_sky_Temperature - cold sky temperature # cold_sky_average_time - cold sky calibration time duration # target_temperature - target temperature # norm_rl_count : expected RL count when Trlotmp=300 K, 262000 # radiometer_cal_gain : radiometer calibrated gain using Saturn, 206.2 1/(K s) # receiver_temperature : 550 K # min_beam_distance - Distance between limb direction and boresight in units of beam oneway 3dB # cold_sky_cal_polynomial_fit_order : nth polynomial fitting # maximum_separation_bet_cold_sky_meas : time between cold sky calibration # radiometer_delta_tau - Parameter for performed radiometer normalization 0 s # radiometer_offset - Parameter for performed radiometer normalization 3550 # noise_diode_delta_tau - noise diode integration time offset # resistive_load_delta_tau - resistive load integration time offset # ND_Rip - Noise Diode Radiometric integration time (used in RMSS) # Max_ND_Rip - Maximum Noise Diode Radiometric integration time when auto rad is on # RL_Rip - Resistive Load Radiometric integration time (used in RMSS) # Max_RL_Rip - Maximum Resistive Load Radiometric integration time when auto rad is on #----------------------------------------------------------------------------- cold_sky_Temperature 2.738 K cold_sky_average_time 30 s target_temperature 91 K norm_rl_count 262000 1/s radiometer_cal_gain 206.2 1/(K s) receiver_temperature 550 K min_beam_distance 2.5 cold_sky_cal_polynomial_fit_order 2 maximum_separation_bet_cold_sky_meas 5 min radiometer_delta_tau -1.175 ms radiometer_offset 3550 noise_diode_delta_tau -0.12 ms resistive_load_delta_tau -0.0405 ms ND_Rip 5 ms Max_ND_Rip 8 ms RL_Rip 25 ms Max_RL_Rip 40 ms #----------------------------------------------------------------------------- # Orphaned keywords: # Need to add these to master config file! #----------------------------------------------------------------------------- AZIMUTH_WIDTH_CUTOFF_ENABLED 0 BIDR_IGNORE_GAPS 1 BIDR_SEGMENT_ID 1 ENABLE_BEAM_FEATHERING 0 ENABLE_NOISE_SUBTRACTION 1 L1I_REPLACE_X 0 Ping_Pong_Data_Rate_Factor 1 Ping_Pong_Noise_Bit_Factor 0.97 SAR_PROC_END_TIME 1098 s SAR_PROC_START_TIME -1098 s SYSTEM_TEMPERATURE_ALTH 790 K SYSTEM_TEMPERATURE_ALTL 894 K SYSTEM_TEMPERATURE_SARH 812 K SYSTEM_TEMPERATURE_SARL 824 K USE_FFT_INTERPOLATION 0 bld230beampatterndir /home/jpl/richw/dat/cassini/beam_patterns/ bld300beampatterndir /home/ras/dat/beam_patterns/ erisSPICEdir /home/ras/dat/naif/ mirror_option yes muhleman_backscatt_model_k1 0.0814 muhleman_backscatt_model_k2 0.0 resistive_load_loss_factor 0.8 sciop3SPICEdir /cas/ancillary/ops/NAIF/ sciop5SPICEdir /cas/ancillary/ops/NAIF/ use_multilook_ambiguity 0 zero_range_time_delay 9.8e-6 s # Keywords accessed by: # CONFIG_INTERACTIVE_MODE_ON # ENABLE_ALL_WARNINGS # altitude1 # altitude10 # altitude11 # altitude12 # altitude13 # altitude14 # altitude15 # altitude16 # altitude17 # altitude18 # altitude19 # altitude2 # altitude20 # altitude21 # altitude3 # altitude4 # altitude5 # altitude6 # altitude7 # altitude8 # altitude9 # angle_profile_option # ckernel # ckernel_directory # data_take_number # debug_filename # debug_level_1 # debug_routine_name_1 # end_time # epoch_accuracy # epoch_selection # epoch_time # frame_kernel # incidenceAngle1 # incidenceAngle10 # incidenceAngle11 # incidenceAngle12 # incidenceAngle13 # incidenceAngle14 # incidenceAngle15 # incidenceAngle16 # incidenceAngle17 # incidenceAngle18 # incidenceAngle19 # incidenceAngle2 # incidenceAngle20 # incidenceAngle21 # incidenceAngle3 # incidenceAngle4 # incidenceAngle5 # incidenceAngle6 # incidenceAngle7 # incidenceAngle8 # incidenceAngle9 # instrument_kernel # ivd_time_pad # noise_diode_delta_tau # number_of_altitude_incidenceAngle_variations # planet_ephemeris_kernel # planetary_constants_kernel # polynomial_power # radiometer_delta_tau # radiometer_offset # resistive_load_delta_tau # sc_orientation # sclk_kernel # set_azimuth_rotation # set_sc_z_rotation # solarsystem_ephemeris_kernel # spacecraft # spice_directory # start_time # t_feed_filename # t_hga_filename # t_scwg_filename # target # target_lat_lon_option # time_kernel # time_step # tour_ephemeris # tracking_option # zero_range_time_delay_alth # zero_range_time_delay_sarh # zero_range_time_delay_sarl # zero_range_time_delay_scatt